US6775548B1 - Access channel for reduced access delay in a telecommunications system - Google Patents
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- US6775548B1 US6775548B1 US09/102,222 US10222298A US6775548B1 US 6775548 B1 US6775548 B1 US 6775548B1 US 10222298 A US10222298 A US 10222298A US 6775548 B1 US6775548 B1 US 6775548B1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W28/00—Network traffic management; Network resource management
- H04W28/16—Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]
- H04W28/18—Negotiating wireless communication parameters
- H04W28/22—Negotiating communication rate
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- This invention relates to telecommunications systems and, more particularly, to a method and apparatus for accessing a system utilizing an access channel providing reduced access delay in a telecommunications system.
- GSM Global Services for Mobile
- IS-95A the TIA/EIA/IS-95 Mobile Station-Base Station Compatibility Standard for Dual Mode Wide Band Spread Spectrum Cellular Systems
- IS-136 the TIA/EINIS-136 Mobile Station-Base Station Compatibility Standard
- AMPS/TACS TIA/EIA 553 Analog Standard
- PCS personal communications system
- GSM Global System for Mobile Communications
- a call establishment begins either by a base station transmitting a paging message to a mobile station on a paging channel and then the mobile station transmitting a paging response message to the base station on an access channel, or by a mobile station accessing the system on an access channel by transmitting an origination message to a base station.
- the mobile station In either of these call establishment cases, the mobile station must access the system on an access channel, and information unique to the particular call establishment must be exchanged between the mobile station and base station over the access channel or other channels of the system air interface.
- the paging response message and origination message typically carry a large portion of the information.
- the information unique to the particular call establishment could include called number data, mobile station identification and capability related data, authentication information, etc. After receiving this information, the system must then use the information to set up the different layers of communication necessary in the system to implement the call.
- a mobile station establishes a connection with the base station when it has one or more data packets in the buffer of the mobile station to send or when it is paged by a base station having data packets to send.
- the mobile station accesses the system for a channel connection and transmits until it is determined that no data exists in the buffer for transmission. Since data may be received from a data server at the mobile or base station intermittently, it may be necessary to release the channel connection in order to maximize the use of the channel by other mobile stations. This means that the mobile station will be making multiple access attempts to establish a channel connection, each access attempt being made when the mobile or base station has enough data to transmit. Each access attempt may in itself involve more than one access attempt if initial access attempts are unsuccessful.
- the access channel has a fixed frame size and data rate.
- the IS-95B packet data access channel is the same channel used to originate regular calls.
- the IS-95B access channel has a frame size of 20 msec and a data rate of 4.8 kbps.
- Another object of this invention is to provide a method and apparatus for accessing a telecommunications system using a channel providing reduced access delay.
- Another object of this invention is to provide a method and apparatus for accessing a telecommunications system using a channel having variable data rates and frame sizes for access.
- a further object of this invention is to provide a method and apparatus for accessing a telecommunications system using a channel having variable data rates and frame sizes assignable to a mobile station based on channel conditions and service type required.
- the present invention provides an improved method and apparatus for accessing a telecommunications system.
- the method and apparatus utilizes a channel having variable data rates and frame sizes.
- access to the system may be requested via at least one channel having variable data rates.
- Each of the available data rates is associated with at least one transmission frame size of a plurality of frame sizes. If channel conditions allow, a higher data rate of the available data rates may be used to request access over the channel.
- the method and apparatus has an advantage for use in packet data services. By dynamically determining the data rate based on channel conditions, overall access delays for mobile stations using packet data services and making many access attempts may be reduced.
- a plurality of access channel data rates and frame durations are available for use by a mobile station requesting access.
- the data rates and frame durations may be set so that the number of data bits per frame is constant for ease of processing.
- a mobile station accessing the system selects a data rate and associated frame duration based on channel conditions, mobile station power conditions or the type of service required. Packet data service users requiring shorter access delay may select a higher data rate and associated frame duration for a particular type of service under certain channel conditions, subject to transmission power requirements.
- Transmission power requirements may be determined on the basis of a desired Eb/No to be received at the base station antenna for access attempts by the mobile station.
- the mobile station determines whether an estimated path loss is less than a maximum allowable path loss for a desired data rate for access. If the estimated path loss is less than the maximum allowable path loss at the desired data rate for access and the mobile station transmission power necessary to achieve the desired Eb/No does not exceed the maximum allowed power the mobile station is limited to for acceptable system performance, the desired data rate is selected.
- a lower data rate having a maximum allowable path loss greater than the estimated path loss and/or greater than the maximum allowed power for the mobile station is selected.
- FIG. 1 illustrates a block diagram of a telecommunications system constructed according to an embodiment of the present invention
- FIG. 2 is a block diagram of portions of a mobile station of the embodiment of the invention shown in FIG. 1;
- FIG. 3 is a block diagram of portions of a base station of the embodiment of the invention shown in FIG. 1;
- FIGS. 4A and 4B are illustrations of an access probe transmission and access probe sequence, respectively, according to an embodiment of the invention.
- FIG. 5 is a flow diagram illustrating process steps performed when accessing a system according to an embodiment of the invention.
- FIG. 1 illustrates a block diagram of a telecommunications system 100 constructed according to an embodiment of the present invention.
- System 100 comprises mobile station 114 , and an infrastructure comprising system controller and switch 112 and base stations 102 , 104 , 106 , 108 and 110 .
- a subscriber who subscribes to service provided by the operator of cellular system 100 may use mobile station 114 to make and receive phone calls over a radio interface, such as shown by radio interface 118 between mobile station 114 and base station 108 , as the subscriber moves throughout the coverage area of cellular system 100 .
- the subscriber also may use mobile station 114 to make and receive packet switched data calls over the radio interface 118 .
- mobile station 114 may function as a data terminal for transmitting or receiving data.
- mobile station 114 may be connected to a portable computer or fax machine.
- Each of base stations 102 , 104 , 106 , 108 and 110 provides coverage over a separate area of system 100 , shown as cell A, cell B, cell C, cell D and cell E, respectively, in FIG. 1 .
- Base stations 102 , 104 , 106 , 108 and 110 are connected to system controller and switch 112 by connections as in a conventional cellular system.
- System controller and switch 112 may be connected to a public switched telephone network to allow subscribers of cellular system 100 to make and receive phone calls from the landline public network.
- cell A, cell B, cell C and cell D are shown to be of about the same size and may be the size of what is commonly called a “microcell” or a cell of about 500 meters in width.
- a micro cell of system 100 may require a maximum mobile station transmission power level of approximately 200 mw.
- Cell E of system 100 is shown to be contained within the coverage area of cell C and may be the size of what is commonly called a “picocell” or a cell of about 100 meters in width.
- a picocell of system 100 may require a maximum mobile station transmission power level of approximately 20 mw.
- the embodiment of the invention has particular application to packet data users operating in a microcell or picocell environment.
- cellular system 100 may operate according to the Code Division Multiple Access (CDMA) cellular system standard specified in the document, “The CDMA 2000 ITU-R RTT Candidate submission,” published by the Telecommunications Industry Association, TR45.5 Subcommittee, Apr. 2, 1998 (CDMA 2000).
- CDMA 2000 Code Division Multiple Access
- the method and apparatus of the invention has application to all types of telecommunications systems that use similar access principles, such as, for example, time division multiple access (TDMA) systems.
- TDMA time division multiple access
- Mobile station 114 comprises antenna 200 , duplexer 202 , transmit power amplifier 204 , analog receiver 206 , transmit power controller 208 , searcher receiver 210 , digital data receiver 212 , digital data receiver 214 , diversity combiner/decoder 216 , control processor 218 , user digital vocoder 220 , transmit modulator 222 and user interface 224 .
- Antenna 200 is coupled to analog receiver 206 through duplexer 202 .
- Signals received at antenna 200 are input to analog receiver 206 through duplexer 202 .
- the received signals are then converted to an IF frequency and then filtered and digitized in analog receiver 206 for input to digital data receiver 212 , digital data receiver 214 and searcher receiver 210 .
- the digitized IF signal input to digital data receiver 212 , digital data receiver 214 and searcher receiver 210 may include signals from many ongoing calls, together with the pilot carriers transmitted by the base station of the cell site in which the mobile station is currently located, plus the pilot carriers transmitted by the base stations in all neighboring cell sites.
- Digital data receiver 212 and digital data receiver 214 perform correlation on the IF signal with a pseudo random noise (PN) sequence of a desired received signal.
- the output of digital data receivers 212 and 214 is a sequence of encoded data signals from two independent paths.
- Searcher receiver 210 scans the time domain around the nominal time of a received pilot signal of a base station for other multi-path pilot signals from the same base station and for other signals transmitted from different base stations. Searcher receiver 210 measures the strength of any desired waveform at times other than the nominal time. Searcher receiver 210 generates signals to control processor 218 indicating the strengths of the measured signals to control processor 218 .
- the encoded data signals output from digital data receiver 212 and digital data receiver 214 are input to diversity combiner/decoder 216 .
- diversity combiner/decoder 216 the encoded data signals are aligned and combined, and the resultant data signal is then decoded using error correction and input to digital vocoder 220 .
- Digital vocoder 220 then outputs information signals to the user interface 224 .
- User interface may be a handset with a keypad or another type of user interface, such as a laptop computer monitor and keyboard.
- a signal received at user interface 224 is input to user digital vocoder 220 in digital form as, for example, data or voice that has been converted to digital form at user interface 224 .
- digital vocoder 220 the signal is encoded and output to transmit modulator 222 .
- Transmit modulator 222 Walsh encodes the signal and then modulates the Walsh encoded signal onto a PN carrier signal, with the PN carrier sequence being the PN carrier sequence of the CDMA channel to which the mobile station is assigned.
- the PN carrier information is transmitted to mobile station 114 from the system 100 and transferred to control processor 218 from digital data receivers 212 and 214 after being received from the system. Control processor 218 sends the PN carrier information to transmit modulator 222 .
- the PN modulated signal is then output from transmit modulator 222 to transmit power controller 208 .
- Transmit power controller 208 sets the level of the transmission power of mobile station 114 according to commands received from control processor 218 .
- the transmission power is dependent on the data rate and frame size used for access.
- Control processor 218 also generates commands that set the transmission data rate and frame sizes used for access.
- the power control commands may be generated by control processor 218 according to commands received from the system or may be generated by software of control processor 218 , according to the embodiment of the invention, in response to data received from th e system through digital data receivers 212 and 214 .
- the modulated signal is then output from transmit power controller 208 to transmit power amplifier 204 where the signal is amplified and converted to an IF frequency signal.
- the IF frequency signal is then output from power amplifier 204 to duplexer 20 2 and transmitted from antenna 200 .
- Base station 110 includes a first receiver section 332 , a second receiver section 334 , control processor 322 , diversity combiner/decoder 324 , transmit power controller 326 , digital link 328 , input/out I/O 336 , transmit modulator 330 , control channel transmitter/modulator 320 , transmit power amplifier 310 , and antenna 304 .
- First receiver section 332 comprises antenna 300 , analog receiver 306 , searcher receiver 312 and digital data receiver 314 .
- Second receiver section 334 comprises antenna 302 , analog receiver 308 , searcher receiver 316 and digital data receiver 318 .
- First receiver section 332 and second receiver section 334 provide space diversity for a single signal that may be received at both antennas 300 and 302 .
- the signals received at antenna 300 are input to analog receiver 306 where the signal is filtered, converted to an IF frequency and digitized to generate a digital signal.
- the digital signal is then output from analog receiver 306 to searcher receiver 312 and digital data receiver 314 .
- Searcher receiver 312 scans the time domain around the received signal to verify that digital data receiver 314 tracks the correct signal.
- Control processor 322 generates the control signals for digital data receiver 314 according to a signal received from the searcher receiver 312 , so that the correct signal is received at digital data receiver 314 .
- Digital data receiver 314 generates the proper PN sequence necessary to decode the digital signal received from analog receiver 306 and generates weighted output symbols for input to diversity combiner/decoder 324 .
- Antenna 302 , analog receiver 308 , searcher receiver 316 and digital data receiver 318 of second receiver section 334 function identically to the components of first receiver section 332 to generate a second set of weighted output symbols.
- the weighted symbols from digital data receiver 314 and digital data receiver 318 are then combined and decoded in diversity combiner/decoder 324 to generate received digital data which is then output through digital link 328 and I/O 336 to system controller and switch 112 of FIG. 1 .
- Base station 100 When data received from system controller and switch 112 is to be transmitted from base station 110 on a traffic channel, the data is received at digital link 328 over I/O 336 and sent to transmit modulator 330 . Transmit modulator 330 then modulates the data using the appropriate Walsh function assigned to the mobile station to which the base station is transmitting. The Walsh modulated data is then spread by a voice channel PN sequence having the appropriate time shift and input to transmit power controller 326 . Transmit power controller 326 controls the transmission power in response to control signals received from control processor 322 . The power control commands may be generated by software in control processor 322 . The signal output from power controller 326 is input to transmit power amplifier 310 and then transmitted from antenna 304 . Base station 100 may have multiple transmit modulator and transmit power controllers for transmitting to multiple mobile stations.
- a pilot channel that may be used for handoff measurements is generated by each base station.
- the pilot channel generated for each base station of system 100 is unique, with each pilot identified by the time shift (or phase) of the PN sequence transmitted from the particular base station rather than by a unique PN sequence.
- the pilot channel for base station 110 may be generated in control channel transmitter/modulator 320 in response to control signals generated by control processor 322 .
- the pilot channel signal may be generated by using a Walsh code sequence of all zeros and multiplying the Walsh code sequence by the system PN sequence to generate a pilot channel signal having the appropriate phase for the base station 110 .
- System 100 also utilizes at least one reverse pilot channel and at least one access channel from mobile station 114 to base station 108 . Each access channel is associated with a reverse pilot channel that is generated by using a Walsh code sequence of all zeros. The reverse pilot channel and access channel are used to obtain access to the system.
- FIGS. 4A and 4B therein are illustrated the access channel structure and an access probe sequence, respectively, of an embodiment of the invention.
- the system time is shown as a series of consecutive access channel frames 402 on the system time access.
- the access probe transmission 400 comprises a preamble and a message capsule.
- the access probe transmission 400 has a duration of M ⁇ X msec preamble frames transmitted on the reverse pilot channel plus N ⁇ L msec message capsule frames transmitted on the access channel, where L and X are variable lengths.
- L and X are variable lengths.
- the value of X, M and N may be system constants.
- the N ⁇ L msec message capsule frames may be of duration 20 msec, 10 msec or 5 msec with data rates of 38.4 kbps, 19.2 kbps and 9.6 kbps, respectively.
- the data rates and frame sizes are set so that the number of data bits per frame is constant for ease of processing. It is not required that each data rate be fixed to a specific frame size.
- each data rate may be used with multiple frame sizes of 20 msec, 10 msec or 5 msec.
- the message capsule frames are typically 20 msec in duration.
- the message capsule frame duration is variable.
- Access probes are transmitted as shown in FIG. 4 B.
- An access probe sequence comprises up to 1+NUM_STEP access probes, where NUM_STEP is a system-defined parameter.
- the preamble is transmitted on a reverse pilot channel associated with the access channel.
- the reverse pilot channel space is continuously searched by the base station so mobile station access on the associated access channel can be acquired by the system.
- searcher receivers 312 and 316 , and digital data receivers 314 and 318 are configured to search and receive access probes having multiple frame durations of 5 msec, 10 msec and 20 msec, with multiple data rates of 38.4 kbps, 14.2 kbps and 9.6 kbps.
- Control processor 322 generates the appropriate control signals to cause data and frame rate determination to be performed, so that an access probe is received correctly.
- the reverse pilot channel and channel used for access are spaced by the same long code.
- Each access probe begins with access probe 1 and continues up until access probe 1+NUM_STEP if no acknowledgment is received from the base station after a time-out period denoted by TA.
- Access probe 1 is transmitted at an initial power level, and each succeeding access probe is transmitted at a-power level incremented by PI.
- the power levels used for access are dependent on the message capsule data rate used.
- the power levels for 9.6 kbps are as set for the CDMA 2000 system.
- the initial power level, IP, plus power increment, PI, for different access capsule data rates may be scaled such that for a rate of 19.2 kbps transmit power is 3dB above IP for 9.6 kbps, and for a rate of 38.4 kbps transmit power is 6dB above IP for 9.6 kbps.
- Access probes are separated by the period TA and a random probe backoff time (RT) that are system constants. If no response is received during an access probe sequence, the access probe sequence may be repeated. In an access attempt, the access probe may be repeated up to a number, MAX_SEQ, that is set by the system.
- mobile station 114 when mobile station 114 is involved in a packet data call, mobile station 114 may utilize the variable data rate access probes of the invention to minimize the time needed to obtain access to the system. Mobile station 114 may transmit an access probe to base station 108 in response to a page received on a paging channel or autonomously when mobile station 114 has packet data to be sent.
- the process begins at step 500 .
- the process may begin at initial access for a packet data call or sometime during the duration of an ongoing packet data call, when a physical channel needs to be re-accessed for continued packet data transmission. This may include mobile station 114 or base station 110 initiated accesses.
- searcher receiver 210 of mobile station 114 measures the received signal strength, P pt , of the forward link pilot channel from base station 108 .
- control processor 218 calculates an estimated path loss, L c .
- P pt is the forward link pilot channel transmit power of base station 108 .
- P pt may be fixed based upon the operating environment, cell type, etc., and the value of P pt may be transmitted to mobile station 114 from base station 108 via message signaling.
- the forward link pilot channel measurements of step 502 and calculations of step 504 need not be done after access is required, as these forward link measurements and calculations may be continuously made and already available when mobile station 114 begins the process at step 500 .
- the reference transmission power may be the maximum possible transmit power for mobile station 114 .
- the threshold path loss L 1 may be a system value determined based on a desired Eb/No to give a desired frame error rate (FER) and bit error rate (BER) rate.
- FER frame error rate
- BER bit error rate
- the transmitted power required to achieve a desired Eb/No at base station 118 increases with an increased data rate. Based on a desired FER and BER, then the allowable path loss for transmitting at 9.6 kbps will be greater than the maximum allowable path loss when transmitting at 19.2 kbps at a selected transmission power.
- step 506 If, at step 506 , a determination is made that L c is greater than L 1 , the process moves to step 508 .
- control processor 218 At step 508 , control processor 218 generates the appropriate control signals so that mobile station 114 transmits the access probes of FIGS. 4A and 4B using a message capsule with data transmitted at a rate of 9.6 kbps having a frame of 20 msec in length and initial power IP set for 9.6 kbps.
- the process then ends at step 510 . If, however, at step 506 , a determination is made that L c is not greater than L 1 , the process moves to step 512 .
- the threshold path loss L 2 may be a value determined based on a desired FER and BER.
- control processor 218 determines if the transmit power head room for transmitting at 19.2 kbps exists by determining whether the necessary transmit power for 19.2 kbps to achieve the desired Eb/No with a loss of L c is within the maximum allowable transmit power for mobile station 114 . If a determination is made that the transmit power head room for transmitting at 19.2 kbps exists, the process moves to step 516 . At step 516 , control processor 218 generates the appropriate control signals so that mobile station 114 transmits the access probes of FIGS.
- step 518 If, however, at step 514 , a determination is made that the transmit power head room for transmitting at 19.2 kbps does not exist, the process moves to step 508 and transmits the access probes of FIGS. 4A and 4B using a message capsule with data transmitted at a rate of 9.6 kbps having a frame of 20 msec in length and initial power IP set for 9.6 kbps. The process then ends at step 510 .
- control processor 218 determines if the transmit power head room for transmitting at 38.4 kbps exists by determining whether the necessary transmit power for 38.4 kbps to achieve the desired Eb/No with a loss of L c is within the maximum allowable transmit power for mobile station 114 . If the transmit power head room for transmitting at 38.4 kbps exists, the process moves to step 522 . At step 522 , control processor 218 generates appropriate control signals so that mobile station 114 transmits the access probes of FIGS.
- step 520 a determination is made that power head room for transmitting at 38.4 kbps does not exist, the process moves to step 514 .
- control processor 218 determines if the transmit power head room for transmitting at 19.2 kbps exists. If a determination is made that the transmit power head room for transmitting at 19.2 kbps exists, the process moves to step 516 .
- control processor 218 generates the appropriate control signals so that mobile station 114 transmits the access probes of FIGS. 4A and 4B using a message capsule with data transmitted at a rate of 19.2 kbps having a frame of 10 msec in length and initial power IP set for 19.2 kbps.
- the process then ends at step 518 . If, however, at step 514 , a determination is made that the transmit power head room for transmitting at 19.2 kbps does not exist, the process moves to step 508 and transmits the access probes of FIGS. 4A and 4B using a message capsule with data transmitted at a rate of 9.6 kbps having a frame of 20 msec in length and initial power IP set for 9.6 kbps. The process then ends at step 510 .
- While the embodiment shown utilizes a set frame size for each of the different data rates that may be used for access, it is within the scope of the invention to provide multiple frame sizes for use with each possible data rate. For example, 38.4 kbps could be used with frame sizes of 5, 10 or 20 msec; 19.2 kbps could be used with frame sizes of 10 or 20 msec; and 9.6 kbps could be used with frame sizes of 20 msec. In this case, process steps 516 and 522 may involve access using varying frame sizes. Also, it is within the scope of the invention to determine the access data rate based on predetermined algorithms using parameters other than path loss or to perform the access data rate determination within other than the mobile station. For example, the access data rate may be calculated at the base station, and the appropriate information could then be transmitted to the mobile station to inform the mobile station of the data rate and frame size to use on the access channel.
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